Composite materials

ABSTRACT

A composite material, the composite material comprising at least one prepreg, said prepreg comprising at least one polymeric resin and at least one fibrous reinforcement; and conducting particles dispersed in the polymeric resin.

This application is a divisional of co-pending U.S. application Ser. No.12/221,635, filed on Aug. 5, 2008, which is a continuation ofPCT/GB2007/004220, filed on Nov. 6, 2007.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to composite materials, and particularly,but not exclusively, to fibre reinforced composite materials.

2. Description of Related Art

Composite materials are increasingly used in structural applications inmany fields owing to their attractive mechanical properties and lowweight in comparison to metals. Composites are known in the field toconsist of layering of materials to provide a structurally advantageouslaminate type material. However, whilst electrical conductivity is oneof the most obvious attributes of metals, composite materials based onfibre reinforcements (such as adhesive films, surfacing films, andpre-impregnated (prepreg) materials), generally have much lowerelectrical conductivity.

Conventional composite materials usually consist of a reinforcementphase, generally comprising continuous or discontinuous fibres, and amatrix phase, generally a thermoset or thermoplastic polymer. Most earlyfirst generation matrix polymers for the manufacture of composites were,by nature, brittle and it has therefore been necessary to develop moretoughened versions. The composites materials used as primary structuresin aerospace applications tend to be so-called second or thirdgeneration toughened materials.

There is a particular need for composite materials which exhibitelectrical conductivity for several applications. These applicationsinclude use for protection against lightning strikes, electrostaticdissipation (ESD), and electromagnetic interference (EMI). Priorcomposite materials, such as those based upon carbon fibres, are knownto have some degree of electrical conductivity which is usuallyassociated with the graphitic nature of the carbon filaments. However,the level of electrical conductivity provided is insufficient forprotecting the composite material from the damaging effects of, forexample, a lightning strike.

Second generation toughened composites represent an improvement overearlier first generation materials due to incorporation of tougheningphases within the matrix material. Various methods for increasingelectrical conductivity in these composites have been used. Thesemethods typically include incorporation of metals into the assembly viaexpanded foils, metal meshes, or interwoven wires. Typical metals whichare used for this purpose include aluminium, bronze and copper. Thesecomposite materials can provide better electrical conductivity. However,they are generally heavy and have significantly degraded mechanical andaesthetic properties. These composites are usually found at the firstone or two plies of the material, and therefore a poor overall surfacefinish often results.

In the event of a lightning strike on second generation composites,damage is normally restricted to the surface protective layer. Theenergy of the lightning strike is typically sufficient to vaporise someof the metal and to burn a small hole in the mesh. Damage to theunderlying composite may be minimal, being restricted to the top one ortwo plies. Nevertheless, after such a strike it would be necessary tocut out the damaged area and make good with fresh metal protection and,if required, fresh composite.

As already mentioned, materials with carbon fibres do possess someelectrical conductivity. However, the conductivity pathway is only inthe direction of the fibres, with limited ability for dissipation ofelectrical current in directions orthogonal to the plane of the fibrereinforcement (z direction). Carbon reinforced materials often comprisean interleaf structure which results in inherently low conductivity inthe z direction due to the electrical insulation properties of theinterleaf. The result of such an arrangement can lead to disastrouseffects when damaged by lightning as the electrical discharge can enterthe interleaf, volatilise the resin therein, and cause mass delaminationand penetration through the composite material.

So-called third generation toughened composite materials are based oninterleaf technology where resinous layers are alternated with fibrereinforced plies, and provide protection against impacts. However, theseresin layers act as an electrical insulator and therefore electricalconductivity in the z direction of the material is poor (i.e. orthogonalto the direction of the fibres). Lightning strikes on the compositematerial can result in catastrophic failure of the component, with ahole being punched through a multiple ply laminate.

SUMMARY OF THE INVENTION

The present invention therefore seeks to provide a composite materialwhich has improved electrical conductivity properties in comparison toprior attempts as described herein, and has little or no additionalweight compared to a standard composite material. The present inventionalso seeks to provide a composite material which has the improvedelectrical conductivity without detriment to the mechanical performanceof the material. The present invention further seeks to provide a methodof making the composite material having improved electrical conductivityproperties. A further aim is to provide a lightning strike tolerantcomposite material which is convenient to manufacture, use, and repair.

According to a first aspect of the present invention there is provided acomposite material comprising;

i) a first conductive layer comprising a plurality of electricallyconductive fibres;

ii) a second conductive layer comprising a plurality of electricallyconductive fibres;

iii) a resin layer located between said first conductive fibrous layerand said second conductive fibrous layer, said resin layer comprisingnon-electrically conductive polymeric resin; and

iv) a plurality of conductive bridges extending between said firstconductive fibrous layer and said second conductive fibrous layerwherein each of said conductive bridges consists of a singleelectrically conductive particle.

According to a second aspect of the present invention there is provideda method of making a composite material comprising the steps of;

i) providing a first conductive layer comprising a plurality ofelectrically conductive fibres;

ii) providing a second conductive layer comprising a plurality ofelectrically conductive fibres;

iii) providing a resin layer located between said first conductivefibrous layer and said second conductive fibrous layer, said resin layercomprising non-electrically conductive polymeric resin; and

iv) providing a plurality of conductive bridges extending between saidfirst conductive fibrous layer and said second conductive fibrous layerwherein each of said conductive bridges consists of a singleelectrically conductive particle.

According to a third aspect of the present invention electricallyconductive nano materials are included in addition to the conductivebridges in order to increase conductance through the resin layer.

Surprisingly, it has been found that use of conducting particles in apolymeric resin of a prepreg forms conductive bridges across thenon-conductive resin interleafs or layers to provide reduced bulkresistivity, thereby improving z directional electrical conductivitythrough the composite material. Additionally, it has been found that theconducting particles dispersed in the resin formulation, andsubsequently prepregged, result in a prepreg having substantiallysimilar handling characteristics in comparison with an equivalentunmodified prepreg.

The above described and many other features and attendant advantages ofthe present invention will become better understood by reference to thefollowing detailed description when taken in conjunction with theaccompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified representation of a cross-sectional view(photomicrograph) of a laminate made according to Example 17 wherein 20in silver-coated solid glass spheres form conductive bridges that extendacross the resin interleave layers and electrically connect adjacentlayers of carbon fibres in accordance with the present invention.

FIG. 2 is a simplified representation of a cross-sectional view of alaminate made according to Example 11 wherein 100 μm silver-coated solidglass spheres form conductive bridges across wider resin interleaflayers.

DETAILED DESCRIPTION OF THE INVENTION

It is understood that references to a composite material includematerials which comprise a fibre reinforcement, where the polymericresin is in contact with the fibre but not impregnated in the fibre. Theterm composite material also includes an alternative arrangement inwhich the resin is partially embedded or partially impregnated in thefibre, commonly known in the art as prepreg. The prepreg may also have afully impregnated fibrous reinforcement layer. The composite materialmay also include multilayered materials which have multiplefibre-resin-fibre layers.

It is understood that references to “interleaf structure” refers to themulti-layered material having a fibre-resin-fibre structure. The term“interleaf” refers to the polymeric resin layer which is present, andinterleaved, between the fibre layers. References to “interleafthickness” or “polymeric resin layer thickness” are to the averagedistance across the interleaf layer as measured from the uppermostsurface of a lower or first fibre ply to a lowermost surface of an upperor second fibre ply. The interleaf thickness is therefore equivalent tothe thickness of the interleaved polymeric resin layer, and referencesto interleaf thickness and polymeric resin layer thickness areinterchangeable.

The terms interlayer, interleaf resin layer, resin layer, interplayresin layer, and fibre free layer as used herein are allinterchangeable, and refer to the polymeric resin layer.

The term polymeric resin as used herein refers to a polymeric system.The term “polymeric resin” and “polymeric system” are usedinterchangeably in the present application, and are understood to referto mixtures of polymers having varying chain lengths. The term polymerictherefore includes an embodiment where the resins present are in theform of a resin mixture comprising any of monomers, dimers, trimers, orprepolymers having chain length greater than 3 monomers. The resultingpolymeric resin when cured forms a cross-linked matrix of resin.

Bulk resistivity refers to the measurement of the “bulk” of “volume”resistivity of a semi-conductive material. It can be seen that referenceto an “initial bulk resistivity” relates to the bulk resistivity of apolymeric resin prior to addition of conducting particles. The value inOhms-m is the inherent resistance of a given material. Ohms-m (Ωm) isused for measuring the conductivity of a three dimensional material. Thebulk electrical resistivity ρ of a material is usually defined by thefollowing:

$\rho = \frac{RA}{l}$

where:

ρ is the static resistivity (measured in ohm metres).

R is the electrical resistance of a uniform specimen of the material(measured in others),

l is the length of the specimen (measured in metres)

A is the cross-sectional area of the specimen (measured in squaremetres)

In the present invention, the volume resistivity is only measured in thez-direction (through the composite material thickness). In every case itis referenced as the “volume” resistivity as the thickness is alwaystaken into consideration in the calculation.

As demonstrated in Comparative Examples 1-5, incorporation ofelectrically conductive particles into a non-conductive polymeric resinat concentrations of below 20 vol. % has little effect on the electricalresistance of the resin. However, as demonstrated in Comparative Example6 and Examples 7-15, the same concentration of electrically conductiveparticles, when located in the resin interleaf layer, provide a largedecrease in the bulk resistance of the composite material. Thissurprising decrease in bulk resistance is believed to be due to theelectrically conductive particles becoming oriented in the interleaflayer so as to function as conductive bridges between the fibre layers.The particles do not function as conductive bridges when they arerandomly oriented and distributed in the resin alone.

Furthermore, it has been found that addition of conductive nanomaterials in the interleaf layer provides an additional reduction inresistance that is believed to be due to the nano materials forminginterconnections between the various conductive bridges that are formedby the conducting particles. The addition of conducting particles, suchas carbon particles or silver coated glass spheres, to the compositematerial reduces bulk resistivity and therefore provides electricalconductance levels which exceed those that might have been reasonablyexpected.

A further benefit of the invention is an improved thermal conductivityfor the prepreg, leading to faster heat up times and better dissipationof the heat generated during the cure exotherm. A still further benefitis that the electrical resistance of the composite material isessentially unchanged with variation in temperature.

The reduction in bulk resistivity and improvement in conductivityresults in improved lightning strike performance. This improvementachieved by the present invention is therefore surprising in view of thelow levels of electrically conductive particles employed, and the highelectrical resistivity normally exhibited by the interleaf resin itself.

It is envisaged that the terms “resistivity” and “conductivity” usedherein refer to electrical resistivity and electrical conductivity,respectively.

As used herein, the term “particles” refers to discrete threedimensional shaped additives which are distinct, treated as anindividual units, and separable from other individual additives, butthis does not preclude additives from being in contact with one another.The term embraces the shapes and sizes of electrically conductiveparticles described and defined herein.

The term “aspect ratio” used herein is understood to refer to the ratioof the longest dimension to the shortest dimension of a threedimensional body. The term is applicable to additives of any shape andsize as used herein. Where the term is used in relation to spherical orsubstantially spherical bodies, the relevant ratio would be that of thelargest cross sectional diameter with the smallest cross sectionaldiameter of the spherical body. It will therefore be understood that aperfect sphere would have an aspect ratio of 1 (1:1). The aspect ratiosas specified herein for electrically conductive particles are based onthe dimensions of the particles after any metal coating has beenapplied.

References to the size of the electrically conductive particles are tothe largest cross sectional diameter or dimension of the particles.

Suitable electrically conductive particles may include, by way ofexample, spheres, microspheres, dendrites, beads, powders, any othersuitable three-dimensional additives, or any combination thereof.

The conductive particles used in the present invention may comprise anysuitable conducting particles that are capable of being oriented withinthe interleaf resin thickness so as to form conductive bridges. It willbe understood that this would include any suitable conductive particlescapable of reducing bulk resistivity and thereby facilitating electricalconductivity of the composite material.

The electrically conductive particles may be selected from metal coatedconducting particles, non-metallic conducting particles, or acombination thereof.

The conductive particles are dispersed in the polymeric resin. It isenvisaged that the term “dispersed” may include where the conductiveparticles are present substantially throughout the polymeric resinwithout being present in a substantially higher concentration in anypart of the polymeric resin. Additionally, the term “dispersed” alsoincludes the conductive particles being present in localised areas ofpolymeric resin if reduced bulk resistivity is only required in specificareas of the composite material.

The metal coated conducting particles may comprise core particles whichare substantially covered by a suitable metal.

The core particles may be any suitable particles. Suitable particles, byway of example, include those formed from polymer, rubber, ceramic,glass, mineral, or refractory products such as fly ash.

The polymer may be any suitable polymer which is a thermoplastic orthermosetting polymer. The terms ‘thermoplastic polymer’ and‘thermosetting polymer’ are as characterised herein.

The core particles formed from glass may be any of the types used formaking solid or hollow glass microspheres.

Examples of suitable silica containing glass particles include sodaglass, borosilicate, and quartz. Alternatively, the glass may besubstantially silica free. Suitable silica free glasses include, by wayof example, chalcogenide glasses.

The core particles may be porous or hollow or may themselves be acore-shell structure, for example core-shell polymer particles. The coreparticles may be first coated with an activating layer, adhesionpromoting layer, primer layer, semi-conducting layer or other layerprior to being metal coated.

The core particles are preferably hollow particles formed from glass.Use of hollow core particles formed from glass may be advantageous inapplications where weight reduction is of particular importance.

Mixtures of the core particles may be used to obtain, for example, lowerdensities or other useful properties, for instance a proportion ofhollow metal coated glass particles may be used with a proportion ofmetal coated rubber particles to obtain a toughened layer with a lowerspecific gravity.

Metals suitable for coating the core particles include, by way ofexample, silver, gold, nickel, copper, tin, aluminium, platinum,palladium, and any other metals known to possess high electricalconductivity.

Multiple layers of metal coatings may be used to coat the coreparticles, for example gold coated copper, or silver coated copper.Simultaneous deposition of metals is also possible, thereby producingmixed metal coatings.

The metal coating may be carried out by any of the means known forcoating particles. Examples of suitable coating processes includechemical vapour deposition, sputtering, electroplating, or electrolessdeposition.

The metal may be present as bulk metal, porous metal, columnar,microcrystalline, fibrillar, dendritic, or any of the forms known inmetal coating. The metal coating may be smooth, or may comprise surfaceirregularities such as fibrils, or bumps so as to increase the specificsurface area and improve interfacial bonding. However, the surface mustbe sufficiently regular to provide a solid electrical connection withthe fibrous layer.

The metal coating may be subsequently treated with any of the agentsknown in the art for improving interfacial bonding with the polymericresin, for example silanes, titanates, and zirconates.

The electrical resistivity of the metal coating should be preferablyless than 3×10⁻⁵ Ωm, more preferably less than 1×10⁻⁷ Ωm, and mostpreferably less than 3×10⁻⁸ Ωm.

The metal coated conducting particles may be of any suitable shape forexample spherical, ellipsoidal, spheroidal, discoidal, dendritic, rods,discs, acicular, cuboid or polyhedral. Finely chopped or milled fibresmay also be used, such as metal coated milled glass fibres. Theparticles may have well defined geometries or may be irregular in shape.

The metal coated conducting particles should possess an aspect ratio ofless than 100, preferably less than 10, and most preferably less than 2.

The metal coated conducting particle size distribution may bemonodisperse or polydisperse. Preferably, at least 90% of the metalcoated particles have a size within the range 0.3 μm to 100 μm, morepreferably 1 μm to 50 μm, and most preferably between 5 μm and 40 μm.

The electrically conductive particles may be non-metallic conductingparticles. It will be understood that this would include any suitablenon-metallic particles not having a metal coating, and capable ofreducing bulk resistivity and thereby facilitating electricalconductivity of the composite material.

Suitable non-metallic coducting particles include, by way of example,graphite flakes, graphite powders, graphite particles, graphene sheets,fullerenes, carbon black, intrinsically conducting polymers (ICPs),including, polypyrrole, polythiophene, and polyaniline), charge transfercomplexes, or any combination thereof.

An example of a suitable combination of non-metallic conductingparticles includes combinations of ICPs with carbon black and graphiteparticles.

The non-metallic conducting particle size distribution may bemonodisperse or polydisperse. Preferably, at least 90% of thenon-metallic conducting particles have a size be within the range 0.3 μmto 100 μm, more preferably 1 μm to 50 μm, and most preferably between 5μm and 40 μm.

The electrically conductive particles have a size whereby at least 50%of the particles present in the polymeric resin have a size within 10 μmof the thickness of the polymeric resin layer. In other words thedifference between the thickness of the resin layer and the size of theelectrically conductive articles is less than 10 μm. Preferably theelectrically conductive particles have a size whereby at least 50% ofthe particles present in the polymeric resin have a size within 5 μm ofthe thickness of the polymeric resin layer.

The size of at least 50% of the electrically conductive particles istherefore such that they bridge across the interleaf thickness(polymeric resin layer), and the particles are in contact with an upperfibrous reinforcement ply and a lower fibrous reinforcement ply arrangedabout the polymeric resin layer.

The electrically conductive particles may be present in the range 0.2vol. % to 20 vol. % of the composite material. More preferably, theconducting particles are present in the range 0.4 vol. % to 15 vol. %.Most preferably, the conducting particles are present in the range 0.8vol. % to 10 vol. %.

In an alternative einbodiment, electrically conductive nano materialsmay be present in an amount of less than 10 vol. % of the polymericresin layer to provide supplemental electrical conductivity through theresin layer.

It can be seen that the preferred ranges of the electrically conductiveparticles are expressed in vol. % as the weight of the particles mayexhibit a large variation due to variation in densities.

The electrically conductive particles may be used alone or in anysuitable combination.

Without wishing to be unduly bound by theory, it has been found that thebenefits of the invention may be conferred due to the conductiveparticles (either metal coated or non-metallic) acting as electricalconductance bridges across the interleaf thickness (i.e. across thepolymeric resin layer and between the layers of fibrous reinforcement),thereby connecting plies of fibrous reinforcement and improving the zdirectional electrical conductance.

The conductive bridges that are formed when the size of the electricallyconductive particles is substantially equal to the interleaf thicknessadvantageously allows for electrical conductance across the compositematerial (in the z plane) to be provided at relatively low loadinglevels of conductive particles. As previously mentioned, these lowloading levels of electrically conductive particles are less than wouldbe typically required to make the polymeric resin itself electricallyconducting.

The electrically conductive particles therefore facilitate electricalconductivity by lowering the bulk resistivity of the composite material.

The nano materials used in the above mentioned alternate embodiment maycomprise carbon nano materials. The carbon nano materials may beselected from carbon nanotubes, and carbon nanofibres. The carbon nanomaterials may be any suitable carbon nanotubes or carbon nanofibres.

The carbon nano materials may have a diameter in the range 10-500 nm.Preferred carbon nano materials may have a diameter in the range 100 to150 nm. The carbon nano materials may preferably have a length in therange 1-10 μm.

The carbon nano materials provide additional electrically conductingpathways through the composite material (in the x,y and z planes) byfurther bridging between the conductive particles and across theinterleaf.

The fibrous reinforcements are arranged in the form of layers or pliescomprising a number of fibre strands. The composite material comprisesat least two fibrous reinforcement plies which are arranged either sideof a polymeric resin layer. As well as providing electrical conductivityin the x and y planes of the material, the plies act as supportinglayers to the structure of the material, and substantially contain thepolymeric resin.

The fibrous reinforcement of the prepreg may be selected from hybrid ormixed fibre systems which comprise synthetic or natural fibres, or acombination thereof. The fibrous reinforcement is electricallyconductive, and therefore is formed from fibres which are electricallyconductive.

The fibrous reinforcement may preferably be selected from any suitablematerial such as metallised glass, carbon, graphite, metallised polymerfibres (with continuous or discontinuous metal layers), the polymer ofwhich may be soluble or insoluble in the polymeric resin. Anycombination of these fibres may be selected. Mixtures of these fibreswith non-conducting fibres (such as fibreglass for example) may also beused.

The fibrous reinforcement is most preferably formed substantially fromcarbon fibres.

The fibrous reinforcement may comprise cracked (i.e. stretch-broken) orselectively discontinuous fibres, or continuous fibres. It is envisagedthat use of cracked or selectively discontinuous fibres may facilitatelay-up of the cured composite material prior to being fully curedaccording to the invention, and improve its capability of being shaped.

The fibrous reinforcement may be in the form of woven, non-crimped,non-woven, unidirectional, or multiaxial textile tapes or tows.

The woven form is preferably selected from a plain, satin, or twillweave style. The non-crimped and multiaxial forms may have a number ofplies and fibre orientations.

Such styles and forms of fibrous reinforcement are well known in thecomposite reinforcement field, and are commercially available from anumber of companies including Hexcel Reinforcements of Villeurbanne,France.

The polymeric resin of the prepreg preferably comprises at least onethermoset or thermoplastic resin.

The term ‘thermoset resin’ includes any suitable material which isplastic and usually liquid, powder, or malleable prior to curing anddesigned to be moulded in to a final form. The thermoset resin may beany suitable thermoset resin. Once cured, a thermoset resin is notsuitable for melting and remoulding. Suitable thermoset resin materialsfor the present invention include, but are not limited to, resins ofphenol formaldehyde, urea-formaldehyde, 1,3,5-triazine-2,4,6-triamine(Melamine), bismaleimide, epoxy resins, vinyl ester resins, benzoxazineresins, phenolic resins, polyesters, unsaturated polyesters, cyanateester resins, or any combination thereof.

The thermoset resin is preferably selected from epoxide resins, cyanateester resins, bismaleimide, vinyl ester, benzoxazine, and phenolicresins.

The term ‘thermoplastic resin’ includes any suitable material which isplastic or deformable, melts to a liquid when heated and freezes to abrittle, and forms a glassy state when cooled sufficiently. Once formedand cured, a thermoplastic resin is suitable for melting andre-moulding. Suitable thermoplastic polymers for use with the presentinvention include any of the following either alone or in combination:polyether sulphone (PES), polyether ethersulphone (PEES), polyphenylsulphone, polysulphone, polyester, polymerisable macrocycles (e.g.cyclic butylene terephthalate), liquid crystal polymers, polyimide,polyetherimide, aramid, polyamide, polyester, polyketone,polyetheretherketone (PEEK), polyurethane, polyurea, polyarylether,polyarylsulphides, polycarbonates, polyphenylene oxide (PPO) andmodified PPO, or any combination thereof.

The polymeric epoxy resin preferably comprises at least one ofbisphenol-A (BPA) diglycidyl ether and bisphenol-F (BPF) diglycidylether and derivatives thereof; tetraglycidyl derivative of4,4′-diaminodiphenylmethane (TGDDM); triglycidyl derivative ofaminophenols, and other glycidyl ethers and glycidyl amines well knownin the art.

The polymeric resin is applied to the fibrous reinforcement. The fibrousreinforcement may be fully or partially impregnated by the polymericresin. In an alternative embodiment, the polymeric resin may be aseparate layer which is proximal to, and in contact with, the fibrousreinforcement, but does not substantially impregnate said fibrousreinforcement.

The composite material may include at least one curing agent. The curingagent may be substantially present in the polymeric resin. It isenvisaged that the term “substantially present” means at least 90 wt. %of the curing agent, preferably 95 wt. % of the curing agent.

For epoxy resins, the curing agents of the invention are those whichfacilitate the curing of the epoxy-functional compounds of theinvention, and, particularly, facilitate the ring opening polymerisationof such epoxy compounds. In a particularly preferred embodiment, suchcuring agents include those compounds which polymerise with theepoxy-functional compound or compounds, in the ring openingpolymerisation thereof.

Two or more such curing agents may be used in combination.

Suitable curing agents include anhydrides, particularly polycarboxylicanhydrides, such as nadic anhydride (NA), methylnadic anhydride,phthalic anhydride, tetrahydrophthalic anhydride, hexahydrophthalicanhydride, methyltetrahydrophthalic anhydride, methylhexahydrophthalicanhydride, endomethylenetetrahydrophthalic anhydride, or trimelliticanhydride.

Further suitable curing agents are the amines, including aromaticamines, e.g., 1,3-diaminobenzene, 1,4-diaminobenzene,4,4′-diaminodiphenylmethane, and the polyaminosulphones, such as4,4′-diaminodiphenyl sulphone (4,4-DDS), and 3,3′-diaminodiphenylsulphone (3,3′-DDS).

Also, suitable curing agents may include phenol-formaldehyde resins,such as the phenol-formaldehyde resin having an average molecular weightof about 550-650, the p-t-butylphenol-formaldehyde resin having anaverage molecular weight of about 600-700, and thep-n-octylphenol-formaldehyde resin, having an average molecular weightof about 1200-1400.

Yet further suitable resins containing phenolic groups can be used, suchas resorcinol based resins, and resins formed by cationicpolymerisation, such as dicyclopentadiene-phenol copolymers. Stilladditional suitable resins are melamine-formaldehyde resins, andurea-formaldehyde resins.

Different commercially available compositions may be used as curingagents in the present invention. One such composition is AH-154, adicyandiamide type formulation, available from Ajinomoto USA Inc. Otherswhich are suitable include Ancamide 1284, which is a mixture of4,4′-methylenediamine and 1,3-benzenediamine; these formulations areavailable from Pacific Anchor Chemical, Performance Chemical Division,Air Products and Chemicals, Inc., Allentown, USA.

The curing agent(s) is selected such that it provides curing of theresin component of the composite material when combined therewith atsuitable temperatures. The amount of curing agent required to provideadequate curing of the resin component will vary depending upon a numberof factors including the type of resin being cured, the desired curingtemperature, and the curing time. Curing agents typically includecyanoguanidine, aromatic and aliphatic amines, acid anhydrides, LewisAcids, substituted ureas, imidazoles and hydrazines. The particularamount of curing agent required for each particular situation may bedetermined by well-established routine experimentation.

Exemplary preferred curing agents include 4,4′-diaminodiphenyl sulphone(4,4-DDS) and 3,3′-diaminodiphenyl sulphone (3,3′-DDS).

The curing agent, if present, may be present in the range 45 wt. % to 2wt. % of the composite material. More preferably, the curing agent maybe present in the range 30 wt. % to 5 wt. %. Most preferably, the curingagent may be present in the range 2.5 wt. % to 5 wt. %.

Accelerators, if present, are typically urones. Suitable accelerators,which may be used alone or in combination include N,N-dimethyl,N-3,4-dichlorphenyl urea (Diuron), N′-3-chlorophenyl urea (Monuron), andpreferably N,N-(4-methyl-m-phenylene bis[N′,N′-dimethylurea] (TDIurone).

The composite material may also include additional ingredients such asperformance enhancing or modifying agents. The performance enhancing ormodifying agents, by way of example, may be selected from flexibilisers,toughening agents/particles, additional accelerators, core shellrubbers, flame retardants, wetting agents, pigments/dyes, flameretardants, plasticisers, UV absorbers, anti-fungal compounds, fillers,viscosity modifiers/flow control agents, tackifiers, stabilisers, andinhibitors.

Toughening agents/particles may include, by way of example, any of thefollowing either alone or in combination: polyamides, copolyamides,polyimides, aramids, polyketones, polyetheretherketones, polyaryleneethers, polyesters, polyurethanes, polysulphones, high performancehydrocarbon polymers, liquid crystal polymers, PTFE, elastomers, andsegmented elastomers.

Toughening agents/particles, if present, may be present in the range 45wt. % to 0 wt. % of the composite material. More preferably, they may bepresent in the range 25 wt. % to 5 wt. %. Most preferably, they may bepresent in the range 15 wt. % to 10 wt. %.

A suitable toughening agent/particle, by way of example, is Sumikaexcel5003P, which is commercially available from Sumitomo Chemicals of Tokyo,Japan. Alternatives to 5003P are Solvay polysulphone 105P, and Solvay104P which are commercially available from Solvay of Brussels, Belgium.

Suitable fillers may include, by way of example, any of the followingeither alone or in combination: silicas, aluminas, titania, glass,calcium carbonate, and calcium oxide.

The composite material may comprise an additional polymeric resin whichis at least one thermoset or thermoplastic resins as defined previously.

Whilst it is desirable that the majority of electrically conductiveparticles are located within the polymeric resin of the compositematerial, it is not generally detrimental if a small percentage of suchparticles are distributed within the fibrous reinforcement. Theconducting particles may be suitably dispersed within the polymericresin of the prepreg by conventional mixing or blending operations.

The mixed resin containing all the necessary additives and theconducting particles can be incorporated into prepreg by any of theknown methods, for example a so-called lacquer process, resin filmprocess, extrusion, spraying, printing or other known methods.

In a lacquer process all the resin components are dissolved or dispersedin a solvent and the fibrous reinforcement is dipped in the solvent, andthe solvent is then removed by heat. In a resin film process thepolymeric resin is cast as a continuous film, either from a lacquer or ahot melt resin, onto a substrate which has been treated with a releaseagent, and then the coated film is contacted against the fibrousreinforcement and, under the aid of heat and pressure, the resin filmmelts and flows into the fibres. A multiplicity of films may be used andone or both sides of the fibre layer may be impregnated in this way.

If the prepreg is made by a film or lacquer process, the majority of theconducting particles will be “filtered” by the reinforcing fibres andthus will be substantially prevented from entering the fibrousreinforcement because the particle size is larger than the distancebetween the reinforcing fibres. Accordingly, the particles becomeconcentrated in the interleaf layer where they act as individual spacersor bridges between the fibrous layers. Other processes, such as sprayingor printing would enable the conducting particles to be placed directlyonto the fibrous reinforcement with very low penetration of the saidparticles between the fibres.

When metal coated hollow particles are used, it may be necessary toutilise lower shear mixing equipment to reduce the deforming effect thatmixing may produce on the conducting particles.

The prepreg may be in the form of continuous tapes, towpregs, fabrics,webs, or chopped lengths of tapes, towpregs, fabrics, or webs. Theprepreg may be an adhesive or surfacing film, and may additionally haveembedded carriers in various forms both woven, knitted, and non-woven.

Prepregs formulated according to the present invention may be fabricatedinto final components using any of the known methods, for example manuallay-up, automated tape lay-up (ATL), automated fibre placement, vacuumbagging, autoclave cure, out of autoclave cure, fluid assistedprocessing, pressure assisted processes, matched mould processes, simplepress cure, press-clave cure, or continuous band pressing.

The composite material may be in an embodiment comprising a single plyof conductive fibrous reinforcement, which has applied on one side apolymeric resin layer comprising electrically conductive particles. Thecomposite material may be manufactured in a single ply embodiment andsubsequently be formed in to multiple layers to provide an interleafstructure by lay-up. The interleaf structure is therefore formed duringlay-up where a fibre-resin-fibre configuration arises.

The composite material may therefore comprise a single prepreg.Alternatively, the composite material may comprise a plurality ofprepregs.

The polymeric resin layer thickness of the prepreg is preferably in therange 1 μm to 100 μm, more preferably 1 μm to 50 μm, and most preferably5 μm to 50 μm.

Multiple layers of conductive composite materials may be used. Thus, byway of example, an assembly may be prepared using 12 plies of standardcomposite materials, and 4 plies of composite materials comprisingconducting particles of the present invention, thus enhancing theconductivity of the final assembly. As a further example, a laminateassembly could be prepared from 12 plies of standard compositematerials, and composite material comprising conducting particles andwith no carbon fibre reinforcement. Optionally, where a compositematerial of the present invention is used, an electrically isolatinglayer can be placed between the carbon fibre plies and the resinsurface. For example, a glass reinforced fibrous layer can be used asthe isolating layer. It is understood that there are many possibleassemblies that could be used, and those described herein are by way ofexample only.

A further benefit is that the composite material of the presentinvention, prior to being fully cured, is completely flexible and issuitable for automated tape lay up processes which are increasingly usedin the manufacture of large composite structures in the aerospaceindustry.

The composite material of the invention may be fully or partially curedusing any suitable temperature, pressure, and time conditions known inthe art.

The composite material may be cured using a method selected fromUV-visible radiation, microwave radiation, electron beam, gammaradiation, or other suitable thermal or non-thermal radiation.

Thus, according to a fourth aspect of the present invention there isprovided a method of making a cured composite material comprising thesteps of the second aspect, and subsequently curing the compositematerial.

The curing step of the fourth aspect may be using any known method.Particularly preferred are curing methods as described herein.

Thus according to a fifth aspect of the present invention there isprovided a cured composite material which comprises a composite materialaccording to the first aspect of the present invention, wherein thecomposite material is cured.

Whilst most of the following discussion concentrates on lightning strikeprotection, it will readily be seen that there are many potentialapplications for a composite material exhibiting reduced bulkresistivity and high electrical conductivity. Thus, the level ofconductivity achieved by the present invention will make the resultingcomposite materials suitable for use in electromagnetic shielding,electrostatic protection, current return, and other applications whereenhanced electrical conductivity is necessary.

Furthermore, although much of the discussion centres around aerospacecomponents, it is also possible to apply the present invention tolightning strike and other electrical management problems in windturbines, buildings, marine craft, trains, automobiles and other areasof concern.

It is envisaged that the present invention, when used for aerospacecomponents, can be used for primary structure applications (i.e. thoseparts of the structure which are critical for maintaining the integrityof the airplane), as well as secondary structure applications.

Thus, according to a sixth aspect of the present invention there isprovided a process for making an aerospace article formed from a curedcomposite material comprising the steps of:

-   -   making a cured composite material in accordance with the method        of the fourth aspect    -   using the cured composite material to produce an aerospace        article by a known method.

Thus, according to a seventh aspect of the present invention there isprovided an aerospace article comprising the cured composite material ofthe fifth aspect.

All of the features described herein may be combined with any of theabove aspects, in any combination.

In the following examples, “neat resin” refers to the basic polymericmatrix resin, in the absence of reinforcing fibres, used formanufacturing prepreg.

M21 is a thermoplastic-toughened epoxy resin that is used in theproduction of HexPly® M21. M21 includes a mixture of bifunctional,trifunctional and tetrafunctional epoxies that is toughened with athermoplastic toughening agent. HexPly® M21 is an interleaved prepregmaterial available from Hexcel Composites, Duxford, Cambridge, UnitedKingdom.

LY1556 is an epoxy resin available from Huntsman Advanced Materials,Duxford, Cambridge, United Kingdom.

It will be understood that all tests and physical properties listed havebeen determined at atmospheric pressure and room temperature (i.e. 20°C.), unless otherwise stated herein, or unless otherwise stated in thereferenced test methods and procedures.

Comparative Example 1 Neat Resin

A neat epoxy resin sample of M21 was produced by blending the epoxyresins, curing agent and toughening agent uniformly and curing in athermostatically controlled oven at 180° C. for 2 hours. Surfaceresistivity was then measured for the cured resin plaque using a model272 resistivity meter from Monroe Electronics by placing a circularelectrode on the surface of the neat resin specimen a reading themeasured and displayed value on the instrument panel. It is importantthat contact between the specimen and probe is good, and therefore neatresin samples should be flat, smooth and uniform. Results are shown inTable 1.

Comparative Example 2 Neat Resin with Conductive Particles

Samples of resin (M21) comprising silver coated solid glass spheres(size 20 μm) present at the following levels:

2-1 1.0 vol. % (equivalent to 2.5 wt. %)

2-2 2.0 vol. % (equivalent to 5.0 wt. %)

2-3 3.0 vol. % (equivalent to 7.5 wt. %)

2-4 2-4 4.0 vol. % (equivalent to 10.0 wt. %)

were prepared and cured in an oven at 180° C. for 2 hours. Surfaceresistivity was then measured using the same resistivity meter andprocedure as detailed in Example 1. Results are shown in Table 1.

Comparative Example 3 Neat Resin with Conductive Particles

Samples of resin (M21) comprising silver coated polymethylmethacrylate(PMMA) particles (size 20 μm) present at the following levels:

3-1 2.5 vol. % (equivalent to 2.5 wt. %)

3-2 5.0 vol. % (equivalent to 5.0 wt. %)

3-3 7.5 vol. % (equivalent to 7.5 wt. %)

3-4 10.0 vol. % (equivalent to 10.0 wt. %)

were prepared and cured in an oven at 180° C. for 2 hours. Surfaceresistivity was then measured using a resistivity meter and procedure asdetailed in Comparative Example 1. Results are shown in Table 1.

Comparative Example 4 Neat Resin with Conductive Particles

Samples of M21 epoxy resin comprising silver coated hollow glass spheres(size 20 μm) present at the following levels:

4-1 2.5 vol. % (equivalent to 2.5 wt. %)

4-2 5.0 vol. % (equivalent to 5.0 wt. %)

4-3 7.5 vol. % (equivalent to 7.5 wt. %)

4-4 10.0 vol. % (equivalent to 10.0 wt. %)

were prepared and cured in an oven at 180° C. for 2 hours. Surfaceresistivity was then measured using a resistivity meter and proceduredetailed in Comparative Example 1. Results are shown in Table 1.

The surface resistivity is a measure of resistivity of thin films havinguniform thickness. Surface resistivity is measured in ohms/square(Ω/sq.), and it is equivalent to resistivity for two-dimensionalsystems. The term is therefore a measure of resistivity for a currentpassing along the surface, rather than through the material which isexpressed as bulk resistivity. Surface resistivity is also referred toas sheet resistance.

TABLE 1 Surface resistivity of M21 epoxy resin modified with conductiveparticles. Surface Ex- Loading Loading Resistivity ample Conductiveadditive (vol. %) (wt. %) (Ω/square) 1 No additive 0 0 2.0 × 10¹² 2-1Silver coated solid glass spheres 1.0 2.5 3.4 × 10¹² 2-2 Silver coatedsolid glass spheres 2.0 5.0 3.0 × 10¹² 2-3 Silver coated solid glassspheres 3.0 7.5 2.5 × 10¹² 2-4 Silver coated solid glass spheres 4.010.0 2.6 × 10¹² 3-1 Silver coated PMMA spheres 2.5 2.5 2.4 × 10¹² 3-2Silver coated PMMA spheres 5.0 5.0 3.0 × 10¹² 3-3 Silver coated PMMAspheres 7.5 7.5 1.8 × 10¹² 3-4 Silver coated PMMA spheres 10.0 10.0 1.7× 10¹² 4-1 Silver coated hollow glass spheres 2.5 2.5 2.7 × 10¹² 4-2Silver coated hollow glass spheres 5.0 5.0 2.8 × 10¹² 4-3 Silver coatedhollow glass spheres 7.5 7.5 1.8 × 10¹² 4-4 Silver coated hollow glassspheres 10.0 10.0 1.9 × 10¹²

These results demonstrate that addition of conductive silver particlesat 10 vol. % or lower provides little, if any, reduction in the surfaceresistivity of cured neat epoxy resin. The epoxy resin remainsessentially non-electrically conductive (at least 1×10¹² Ω/square) eventhough conducting particles have been added.

Comparative Example 5 Neat Resin with Carbon Nano Fibres

A neat epoxy resin sample was produced in which LY1556 (50.0 g) wasadded carbon nanofibres (110 nm-150 nm diameter having lengths of 1-10μm) as produced by Electrovac of Austria. Using a Flaktec Speedmixer thefibres were dispersed in the resin at 2500 rpm for 15 minutes. Silvercoated glass beads (20 μm) at 2.0 vol. %, carbon nanofibres at 2.0 wt.%, and 4,4′-diaminodiphenylsulphone were added to the mixture andblended by stirring. The resistivity of neat LY1556 resin is about 10¹²Ω/square. The formulation was cured in a thermostatically controlledoven at 180° C. for 2 hours. Surface resistivity was then measured forthe cured plaque using a model 272 resistivity meter from MonroeElectronics. Results are summarised in Table 2.

TABLE 2 Surface resistivity of epoxy resin modified with silver coatedglass spheres and carbon nanofibres (CNF). 110 nm Silver solid Silvercoated Surface CNFs glass spheres glass spheres Resistivity Example (wt.%) (vol. %) (wt. %) (Ω/square) 1 — — —   2 × 10¹² 2-2 — 2.0 5.0 3.0 ×10¹² 5 2 2.0 5.0 4.7 × 10² 

These results show that the combination of carbon nanofibres with silvercoated glass spheres lowers the surface resistivity of the epoxy resinwhen compared to the neat epoxy resin and epoxy resin that containssilver coated solid glass spheres.

In the following examples, “carbon composite” refers to the basic matrixresin, in the presence of reinforcing carbon fibres, used formanufacturing prepreg.

Comparative Example 6 Carbon Composite

M21 resin was produced by blending the components in a Z-blade mixer(Winkworth Machinery Ltd, Reading, England). The resin was coated as athin film on silicone release paper which was then impregnated onintermediate modulus IM7 unidirectionally oriented carbon fibreavailable from (Hexcel Composites, Duxford, UK) at a resin weight of 35%using a hot press to make a unidirectional prepreg. A five ply prepregwas laid up unidirectionally which was approximately 10 cm by 10 cm andcured on a vacuum table at a pressure of 7 bar at 177° C. for 2 hours. Az-direction electrical resistance value of the composite was determinedfirst by gold sputtering a square on either side of a rectangular shapedsample in order to ensure low contact resistance. Resistivity was thenmeasured by applying probes to the gold sputtered area of the specimensand using a power source (TTi EL302P Programmable 30V/2A Power SupplyUnit, Thurlby Thandar Instniments, Cambridge, UK) that was capable ofvarying either voltage or current.

Example 7 Carbon Composite with Conductive Particles

M21 resin was modified with silver coated solid glass spheres (20 μm) ata range of 0.8-2.4 vol. % of the resin and the components were blendedin a Winkworth mixer. The resin was coated as a thin film on siliconerelease paper and was then impregnated on intermediate modulus IM7carbon fibre at a resin weight of 35% using a hot press to make aunidirectional prepreg. A five ply prepreg of approximately 10 cm by 10cm was laid up unidirectionally and cured on a vacuum table at apressure of 7 bar at 177° C. for 2 hours. A z-direction electricalresistance value was determined according to the method of Example 1.Results are summarised in Table 3.

TABLE 3 Volume resistivity of carbon composite modified with silvercoated glass spheres. Silver coated Silver coated Z-direction glassspheres glass spheres volume resistivity Example (vol. %) (wt. %) (Ωm) 6— — 3.66 7-1 0.8 2 2.13 7-2 1.6 4 1.89 7-3 2.4 6 1.75

The results in Table 3 clearly show a decrease in z-direction volumeresistivity when compared to a neat resin material of Example 6. Theresistivity is further reduced when the amount of silver coated glassspheres is increased in the material.

Example 8 Carbon Composite with Conductive Particles

M21 resin was modified with silver coated hollow glass spheres (20 μm)at a range of 2.5-10.0 vol. % of the resin, and the components wereblended in a Winkworth mixer. The resin was coated as a thin film onsilicone release paper and was then impregnated on intermediate modulusIM7 carbon fibre at a resin weight of 35% using a hot press to make aunidirectional prepreg. A five ply prepreg of approximately 10 cm by 10cm was laid up unidirectionally and cured on a vacuum table at apressure of 7 bar at 177° C. for 2 hours. A z-direction electricalresistance value was determined according to the method of Example 6.Results are summarised in Table 4.

TABLE 4 Volume resistivity of carbon composite modified with silvercoated hollow glass spheres according to Example 8. Silver coated hollowSilver coated hollow Z-direction glass spheres glass spheres volumeresistivity Example (vol. %) (wt. %) (Ωm) 8-1 2.5 2.5 0.116 8-2 5.0 5.00.064 8-3 7.5 7.5 0.032 8-4 10.0 10.0 0.019

The results in Table 4 clearly show a decrease in z-direction volumeresistivity. The resistivity is further reduced with increases in theamount of silver coated hollow glass spheres in the material.

Example 9 Carbon Composite with Conductive Particles

M21 resin was modified with silver coated polymethylmethacrylateparticles 20 μm) at a range of 2.5-10.0 vol. % of the resin. The resinwas produced by blending the components in a Winkworth mixer. The resinwas coated as a thin film on silicone release paper and was thenimpregnated on intermediate modulus IM7 carbon fibre at a resin weightof 35% using a hot press to make a unidirectional prepreg. A five plyprepreg of approximately 10 cm by 10 cm was laid up unidirectionally andcured on a vacuum table at a pressure of 7 bar at. 177° C. for 2 hours.A z-direction electrical resistance value was determined according tothe method of Example 6. Results are summarised in Table 5.

TABLE 5 Volume resistivity of carbon composite modified with silvercoated PMMA spheres. Silver coated Silver coated Z-direction PMMAparticles PMMA particles volume resistivity Example (vol. %) (wt. %)(Ωm) 9-1 7.5 2.5 0.567 9-2 5.0 5.0 0.103 9-3 7.5 7.5 0.110 9-4 10.0 10.00.052

The results in Table 5 clearly show a decrease in z-direction volumeresistivity. The resistivity is further reduced with increases in theamount of silver coated glass spheres in the material.

Comparative Example 10 Carbon Composite with Dendritic ConductiveParticles

M21 resin was modified with dendritic silver/copper (40 μm) at a loadingof 0.30 vol. % of the resin. The resin was produced by blending thecomponents in a Winkworth mixer. The resin was coated as a thin film onsilicone release paper and was then impregnated on intermediate modulusIM7 carbon fibre at a resin weight of 35% using a hot press to make aunidirectional prepreg. A five ply prepreg of approximately 10 cm by 10cm was laid up unidirectionally and cured on a vacuum table at apressure of 7 bar at 177° C. for 2 hours. A z-direction electricalresistance value was determined according to the method of Example 6.Results are summarised in Table 6.

Example 11 Carbon Composite with Conductive Particles

M21 resin was modified with silver coated solid glass beads (100 μm) ata loading of 1.0 vol. % of the resin. A prepreg and composite wasproduced according to example 9. Z-direction electrical resistance valuewas determined as per Example 6. Results are summarised in Table 6.

Example 12 Carbon Composite

M21 resin was modified with silver coated glass fibres (10 μmdiameter×190 μm long) at a loading of 1.25 wt. % of the resin. A prepregand composite was produced according to example 9. Z-directionelectrical resistance value W as determined as per Example 6. Resultsare summarised in Table 6.

TABLE 6 Volume resistivity of carbon composite modified with differentconducting particles. Particles Particles Z-direction volume ExampleConducting particle (vol. %) (wt. %) resistivity (Ωm) 10 Dendritic 0.302.5 12.26 silver/copper (40 μm) 11 Silver coated glass 1.0 2.5 1.10beads (100 μm) 12 Silver coated glass 1.25 2.5 2.89 fibres (190 μm)

The results in Table 6 show a decrease in z-direction volume resistivitywhen spherically shaped (aspect ratio of 1) conductive particles (100μm) are used. In addition, when conductive particles (silver coatedglass fibres) having a relatively high aspect ratio of 19 are used, theresistivity is only modestly reduced. According, a previously mentioned,the aspect ratios for conductive particles are preferably below 10 andmore preferably below 2.

Comparative Example 13 Carbon Composite-Quasi-Isotropic Laminate

M21 prepreg was produced according to Example 12, except that the layersof unidirectional fibres were oriented in +45° to each other to form a 6ply quasi-isotropic (QI) laminate of approximate size 10 cm×10 cm, whichwas cured on a vacuum table at a pressure of 7 bar at 177° C. for 2hours. The glass transition temperature, T_(g), of the QI composite wasdetermined by dynamic thermal analysis from the storage modulus trace,E′, to be 194.5° C., A square sample (3.9 cm×3.9 cm×0.16 cm) was cutfrom the cured panel and the z-direction resistivity measured asfollows. To ensure good electrical contact, the appropriate parts of thecomposite were vacuum coated with gold in the vicinity where connectionwas to be made with the power supply. The resistivity was thendetermined by applying a current of 1 amp from the power supply andmeasuring the resulting voltage.

TABLE 7 Volume resistivity of the QI composite of Comparative Example13. Z-direction Volume Resistivity Direction Lay up and size (Ωm) z QI(3.9 cm × 3.9 cm × 0.16 cm) 19.70

Example 14 QI Carbon Composite with Conductive Particles

M21 resin was modified with 20 μm silver coated glass beads at (2 vol.%, 5 wt. %) and prepreg was produced according to the method of Example13. A 6 ply quasi-isotropic laminate of approximate size 10 cm×10 cm wasprepared and cured on a vacuum table at a pressure of 7 bar at 177° C.for 2 hours. The glass transition temperature (T_(g)) of the compositewas determined as for Comparative Example 13 to be 196.0° C. Thus theaddition of the silver coated beads does not have a deleterious effecton the T_(g). A square sample (3.8 cm×3.8 cm×0.16 cm) was cut from thecured panel and the z-direction resistivity measured as for Example 13.As shown in Table 8, resistivity was significantly improved.

TABLE 8 Volume resistivity of the composite of Example 14. Z-directionVolume Resistivity Direction Lay up and size (Ωm) z QI (3.8 cm × 3.8 cm× 0.16 cm) 0.024

Example 15 QI Carbon Composite with Conductive Particles and NanoMaterial

M21 resin was modified with 20 μm silver coated glass beads at (2 vol.%, 5 wt. %) and carbon nanofibres (150 nm diameter and lengths of 1-10μm) at 2 wt. % of the resin. Prepreg was produced according toComparative Example 13. A 12 ply quasi-isotropic laminate of approximatesize 10 cm×10 cm was prepared and cured on a vacuum table at a pressureof 7 bar at 177° C. for 2 hours. The glass transition temperature(T_(g)) of the composite was determined as for Comparative Example 13 tobe 196.5° C. Thus the addition of the silver coated beads has not had adeleterious effect on the T_(g). A square sample was cut from the curedpanel and the z-direction resistivity measured as for ComparativeExample 13. As is shown in Table 9, resistivity is significantly reducedin comparison to the QI laminate without conductive particles and nanofibres.

TABLE 9 Volume resistivity of the composite of Example 15. Z-directionVolume Resistivity Direction Lay up and size (Ωm) z QI (3.8 cm × 3.8 cm× 0.16 cm) 0.023

Comparative Example 16 Simulated Lightning Strikes with no ConductiveParticles

M21 resin was produced using a Winkworth mixer and then filmed ontosilicone release paper. This resin film was then impregnated ontounidirectional intermediate modulus carbon fibre, using a pilot scaleunidirectional prepregger, which produced a prepreg with an areal weightof 268 g/m² at 35 wt. % of resin. Two six-ply prepregs were produced(lay up±0/90) which were approximately 60 cm by 60 cm and these werecured on a vacuum table at a pressure of 7 bar at 177° C. for 2 hours.

The two panels were tested according to procedures established for Zone1A surfaces, which include surfaces of the aeroplane for which there isa high probability of initial lightning flash attachment (entry or exit)with low probability of flash hang on, such as radomes and leadingedges. Zone 1A also includes swept leaders attachment areas. The zone 1Atest has three waveform components, high current component A (2×10⁶ A,<500 μs), intermediate current component B (average 2 kA, <5 ms) andcontinuing current component C (200C, <1 s). Both surfaces of the panelswere abraded around the edges to ensure a good connection to the outerframe. The electrode was connected to the panel via a thin copper wire.The copper wire provides a path for the current and vaporises on test.It is needed as the voltage generated is not enough to break down theair.

After a simulated lightning strike, Each of the test panels, which didnot comprise metal coated particles, showed severe damage on both theupper surface and lower surface.

An Ultrasonic c-scan was also performed. The Ultrasonic C-scan of thedamaged panels was performed using an R/D Tech Omniscan MX from Olympus.The scan showed that the damage area for the unmodified panels was verylarge.

TABLE 10 Test parameters of lightning strike tests for ComparativeExample 16. A Component B C Panel Current, I Action Integral, ComponentComponent No. (kA) AI (10⁶A²s) current, I (kA) Charge, Q 1 191.7 2.041.74 31.3 2 191.7 2.04 1.72 24.3

TABLE 11 Description of damaged area after lightning strike tests PanelNo. Description of Damage 1 Upper surface; delamination and dry fibres.Unusual scorch mark on surface. 330 mm × 250 mm Bottom surface;delamination and dry fibres. 420 mm × 230 mm. Hole through panel. 2Upper surface; delamination and dry fibres. 280 mm × 270 mm. Bottomsurface; delamination and dry fibres. 510 mm × 180 mm

A large white area was observed on the c-scan. This is where thedelamination of the panels had occurred after the simulated lightningstrike test. This shows that the damaged area is large for panels thatdo not include metal coated particles.

Example 17 Simulated Lightning Strikes with Conductive Particles

M21 resin was modified with 20 μm silver coated glass spheres (2 vol. %,5 wt. % of resin), blended using a Winkworth mixer and then filmed ontosilicone release paper. This resin film was then impregnated ontounidirectional intermediate modulus carbon fibre which produced aprepreg with an areal weight of 268 g/m² at 35 wt. % of resin. Twosix-ply prepregs were produced (lay up ±0/90) which were approximately60 cm by 60 cm and were cured on a vacuum table at a pressure of 7 barat 177° C. for 2 hours. A lightning strike test was then carried out oneach panel according to the method of Comparative Example 16.

The simulated lightning strikes did not penetrate the modified compositepanels.

An Ultrasonic c-scan was carried out on the lightning struck panelsusing an R/D Tech Omniscan MX from Olympus. The scans showed that thewhite areas of the modified panels were reduced in comparison to theunmodified panels of Example 16.

Therefore, the panels with metal coated particles have a much reduceddamage area when compared to the comparative example 16 panels.

TABLE 12 Test parameters of lightning strike tests for Example 17. AComponent B C Panel Current, I Action Integral, Component Component No.(kA) AI (10⁶A²s) current, I (kA) Charge, Q 1 197.1 2.20 1.74 25.0 2195.1 2.10 1.75 29.3

TABLE 13 Description of damaged area after lightning strike tests forExample 17. Panel No. Description of Damage 1 No visible damage to innerskin, split & tufted over 280 × 240 mm on outer skin 2 No visible damageto inner skin, split & tufted over 280 × 220 mm on outer skin

Example 18 Simulated Lightning Strikes with Conductive Particles

M21 resin was modified with silver coated glass spheres (2 vol. %, 5 wt.% of resin and carbon nanofibre (150 nm diameter and 1-10 μm long, 2 wt% of resin) blended using a Winkworth mixer and then filmed ontosilicone release paper. This resin film was then impregnated ontounidirectional intermediate modulus carbon fibre which produced aprepreg with an areal weight of 268 g/m² at 35 wt. % of resin. Twosix-ply prepregs were produced (lay up ±0/90) which were approximately60 cm by 60 cm and were cured on a vacuum table at a pressure of 7 barat 177° C. for 2 hours. A lightning strike test was then carried out oneach panel according to the method of Comparative Example 16.

The simulated lightning strikes did not penetrate the modified compositepanels.

An Ultrasonic c-scan was carried out on the lightning struck modifiedpanels using an R/D Tech Omniscan MX from Olympus. The scan showed thatthe white area of the modified panels was reduced in comparison to theunmodified panel of Comparative Example 16.

Therefore, the modified panels with metal coated particles and carbonnanofibres had a much reduced damage area when compared to the panels ofComparative Example 16.

TABLE 14 Test parameters of lightning strike tests for Example 18. AComponent B C Panel Current, I Action Integral, Component Component No.(kA) AI (10⁶A²s) current, I (kA) Charge, Q 1 198.4 2.20 1.74 25.0 2197.1 2.10 1.75 29.3

TABLE 15 Description of damaged area after lightning strike tests forExample 18. Panel No. Description of Damage 1 No visible damage to innerskin, 300 mm split, tufting over 300 × 200 mm on outer skin. 2 Novisible damage to inner skin, 300 mm split, tufting over 200 × 200 mm onouter skin.

It is therefore shown that use of electrically conductive particles in apolymeric resin of an interleafed composite material provides forreduced resistivity. This reduced resistivity provides improvedperformance of the composite material during lightning strikes as shownin Comparative Example 16 and Examples 17 to 18.

FIG. 1 is a simplified representation 50 of a photomicrograph of a crosssection of a composite panel made according to Example 17. The silvercoated glass spheres 53 are located in the resin interleafs 52, and arecontacting the carbon plies 51. The thickness (t) of the resininterleafs 52 are 20 μm, which corresponds to the diameter of the silvercoated glass spheres 53. As can be seen from FIG. 1, the glassmicrospheres form individual conductive bridges that electrically linkthe carbon plies 51 together and provide spacing between the carbonplies 51.

FIG. 2 is a simplified representation of the cross section of a portionof a composite material 10 made in accordance with Example 11. Thesilver coated glass spheres 13 are located in the resin interleafs 12and are contacting the carbon plies 11. The thickness (t) of the resininterleafs 12 are 100 μm, which corresponds to the diameter of thesilver coated glass spheres 13. As can also be seen from FIG. 2, thelarger glass microspheres form individual conductive bridges thatelectrically link the carbon plies 11 together and provide spacingbetween the carbon plies 11.

Having thus described exemplary embodiments of the present invention, itshould be noted by those skilled in the art that the within disclosuresare exemplary only and that various other alternatives, adaptations andmodifications may be made within the scope of the present invention.Accordingly, the present invention is not limited by the above-describedembodiments, but is only limited by the following claims.

What is claimed is:
 1. An interleaf composite material which is curableto form a panel, that is not penetrated by a lightning strike, saidcomposite material comprising: at least four conductive fibrous layerscomprising a plurality of electrically conductive fibers; electricallyinsulating resin layers located between said conductive fibrous layers,said electrically insulating resin layers each having an averagethickness and comprising a resin formulation comprising a polymericresin; and conductive bridges that extend across said electricallyinsulating resin layers to provide electrical connections between saidconductive fibrous layers wherein said conductive bridges compriseelectrically conductive particles wherein at least 50%, of saidelectrically conductive particles have a diameter that is within 10 μmof the average thickness of said electrically insulating resin layersand wherein the number of said electrically conductive bridges issufficient to prevent penetration of said composite material by alightning strike once said interleaf composite material has been curedto form said panel.
 2. An interleaf composite material according toclaim 1 wherein said electrically conductive particles are present in anamount of between 0.2 vol. % and 2.0 vol. % of said interleaf compositematerial.
 3. An interleaf composite material according to claim 1wherein said resin formulation comprises electrically conductive nanomaterials.
 4. An interleaf composite material according to claim 1wherein said electrically conductive particles comprise anon-electrically conductive core and an electrically conductive coatingsurrounding said core.
 5. An interleaf composite material according toclaim 4 wherein said core comprises a thermoplastic polymer.
 6. Aninterleaf composite material according to claim 1 wherein saidelectrically conductive particles have an aspect ratio of between 1 and10.
 7. An interleaf composite material according to claim 1 wherein saidelectrically conductive fibers are carbon fibers.
 8. An interleafcomposite material according to claim 1 wherein said electricallyconductive particle is a carbon particle.
 9. An interleaf compositematerial according to claim 1 wherein said polymeric resin comprises atoughening agent and/or toughening particles.
 10. An interleaf compositestructure comprising a composite material according to claim 1 whereinsaid polymeric resin has been cured.
 11. A method for making aninterleaf composite material which is curable to form a panel that isnot penetrated by a lightning strike, said method_comprising the stepsof: providing at least four conductive fibrous layers comprising aplurality of electrically conductive fibers; providing electricallyinsulating resin layers located between said conductive fibrous layers,said electrically insulating resin layers each having an averagethickness and comprising a resin formulation comprising a polymericresin; and forming conductive bridges extending across said resin layersto provide an electrical connection between said conductive fibrouslayers wherein said conductive bridges comprise electrically conductiveparticles wherein at least 50% of said electrically conductive particleshave a diameter that is within 10 μm of the average thickness of saidelectrically insulating resin layers and wherein the number of saidelectrically conductive bridges is sufficient to prevent penetration ofsaid composite material by a lightning strike once said interleafcomposite material has been cured to form said panel.
 12. A method formaking an interleaf composite material according to claim 11 whereinsaid electrically conductive particles are present in an amount ofbetween 0.2 vol. % and 20 vol. % of said composite material.
 13. Amethod for making an interleaf composite material according to claim 11wherein said resin formulation additionally comprises electricallyconductive nano materials.
 14. A method for making an interleafcomposite material according to claim 11 wherein said electricallyconductive particle comprises a non-electrically conductive core and anelectrically conductive coating surrounding said core.
 15. A method formaking an interleaf composite material according to claim 14 whereinsaid core comprises a thermoplastic polymer.
 16. A method for making aninterleaf composite material according to claim 9 wherein saidelectrically conductive particles have an aspect ratio of between 1 and10.
 17. A method for making an interleaf composite material according toclaim 11 wherein said electrically conductive fibers are carbon fibers.18. A method for making an interleaf composite material according toclaim 11 that includes the additional step of curing said polymericresin to form said panel.
 19. A method for making an interleaf compositematerial according to claim 11 wherein said electrically conductiveparticle is a carbon particle.
 20. A method for making an interleafcomposite material according to claim 11 wherein said polymeric resincomprises a toughening agent and/or toughening particles.